rotors

简明释义

英[/ˈroʊtərz/]美[/ˈroʊtərz/]

n. [电][机][动力]转子；回转轴（rotor 的复数形式）

英英释义

单词用法

同义词

反义词

例句

1.The present paper offers a method of balancing dynamically the flexible rotors with the technique of modal parameter identification.

本文提出利用模态参数识别技术进行挠性转子动平衡的方法。

2.That distinguishes them from synchronous motors that use a permanent magnet in their rotors instead of a set of aluminium or copper conductors.

这就把它们和在转子处使用永磁铁而非一套铝或铜导体的同步发动机区分开来。

3.The energy contained in the rapidly expanding vapors (other than steam) or gases turns the rotors to produce power of the engine.

包含在快速膨胀的蒸气（不是蒸汽）或气体中的能量使转子旋转并产生发动机的动力。

4.A unique feature of the CV-22 is that its rotors tilt so that it can act either as a helicopter or a plane.

CV - 22非常特别的一点是它的倾转旋翼，它既可以作为直升机也可以作为飞机使用。

5.Turbulence from the rotors has much less consequence in an already turbulent atmosphere.

风轮转子产生的紊流在已经混乱的大气中产生的影响较小。

6.Assuming the new Helicarrier has the same size rotors and mass, these values would be the same.

假设新天空母舰拥有相同的旋翼大小及重量，这些数值将会相同。

7.The helicopter's rotors 旋翼 spun rapidly as it took off from the ground.

直升机的旋翼在起飞时快速旋转。

8.Engineers are testing new materials for the rotors 旋翼 to improve durability.

工程师正在测试新材料用于旋翼以提高耐用性。

9.The drone's rotors 旋翼 allow it to hover in place and maneuver easily.

无人机的旋翼使其能够悬停并轻松操控。

10.Maintenance of the rotors 旋翼 is crucial for safe flight operations.

对旋翼的维护对安全飞行操作至关重要。

11.The sound of the rotors 旋翼 can be heard from miles away when the helicopter is flying.

当直升机飞行时，旋翼的声音可以从几英里外听到。

作文

In the world of engineering and aviation, the term rotors (旋翼) plays a crucial role in the functionality of various machines, particularly helicopters and drones. Understanding how rotors (旋翼) work is essential for anyone interested in aerodynamics or mechanical design. At its core, a rotor (旋翼) is a rotating part of a machine, and it is primarily responsible for generating lift and thrust in flight. Helicopters, for instance, utilize large rotors (旋翼) that spin rapidly to create a difference in air pressure above and below the blades. This difference allows the helicopter to ascend, descend, and maneuver through the air effectively. The design and material composition of these rotors (旋翼) are vital; they must be lightweight yet strong enough to withstand the forces encountered during flight. Engineers spend countless hours testing different shapes and materials to optimize the performance of rotors (旋翼). Moreover, the technology behind rotors (旋翼) has evolved significantly over the years. Modern helicopters often feature advanced composite materials that improve durability and reduce weight. Additionally, innovations such as variable pitch rotors (旋翼) allow pilots to adjust the angle of the blades in real-time, enhancing control and efficiency. This adaptability is particularly beneficial in challenging flying conditions, where precision can mean the difference between a safe landing and a mishap. Drones, which have surged in popularity for both recreational and commercial use, also rely heavily on rotors (旋翼). Most drones are equipped with multiple rotors (旋翼), commonly four, known as quadcopters. Each rotor (旋翼) operates independently, allowing for agile maneuvers and stable flight. The synchronization of these rotors (旋翼) is managed by sophisticated software that calculates the necessary adjustments to maintain balance and direction. The significance of rotors (旋翼) extends beyond just flight; they are also used in various industrial applications. For example, wind turbines harness the power of the wind through large rotors (旋翼) that convert kinetic energy into electrical energy. As the wind blows, the rotors (旋翼) turn, driving a generator that produces electricity. This renewable energy source is critical in our efforts to combat climate change and reduce reliance on fossil fuels. In conclusion, rotors (旋翼) are an integral component of many modern technologies, from aviation to renewable energy. Their ability to generate lift and harness energy makes them invaluable in various fields. As technology continues to advance, the design and functionality of rotors (旋翼) will likely become even more sophisticated, paving the way for new innovations in flight and energy production. Understanding the mechanics and applications of rotors (旋翼) not only highlights their importance but also inspires future generations of engineers and scientists to explore the possibilities they offer.

在工程和航空的世界中，术语rotors（旋翼）在各种机器的功能中发挥着至关重要的作用，特别是直升机和无人机。理解rotors（旋翼）如何工作对于任何对空气动力学或机械设计感兴趣的人来说都是必不可少的。rotor（旋翼）本质上是机器的一个旋转部件，主要负责在飞行中产生升力和推力。 例如，直升机利用大型rotors（旋翼）快速旋转以在刀片的上下方产生气压差。这种差异使直升机能够有效地上升、下降和在空中机动。rotors（旋翼）的设计和材料组成至关重要；它们必须轻便，同时又足够坚固，以承受飞行过程中遇到的力。工程师花费无数小时测试不同的形状和材料，以优化rotors（旋翼）的性能。 此外，rotors（旋翼）背后的技术多年来也发生了显著变化。现代直升机通常采用先进的复合材料，提高耐用性并减少重量。此外，可变俯仰rotors（旋翼）的创新使飞行员能够实时调整刀片的角度，从而增强控制和效率。这种适应性在具有挑战性的飞行条件下尤其有益，在这种情况下，精确度可能意味着安全着陆与事故之间的区别。 无人机近年来因其娱乐和商业用途而迅速普及，也在很大程度上依赖于rotors（旋翼）。大多数无人机配备多个rotors（旋翼），通常是四个，称为四旋翼。每个rotor（旋翼）独立运行，允许灵活的操作和稳定的飞行。这些rotors（旋翼）的同步由复杂的软件管理，该软件计算维持平衡和方向所需的调整。 rotors（旋翼）的重要性不仅限于飞行；它们还用于各种工业应用。例如，风力涡轮机通过大型rotors（旋翼）利用风的力量，将动能转化为电能。随着风的吹动，rotors（旋翼）旋转，驱动发电机产生电力。这种可再生能源在我们努力应对气候变化和减少对化石燃料依赖方面至关重要。 总之，rotors（旋翼）是许多现代技术的不可或缺的组成部分，从航空到可再生能源。它们产生升力和利用能量的能力使它们在各个领域中不可或缺。随着技术的不断进步，rotors（旋翼）的设计和功能可能会变得更加复杂，为飞行和能源生产的新创新铺平道路。理解rotors（旋翼）的机制和应用不仅突显了它们的重要性，还激励未来几代工程师和科学家探索它们所提供的可能性。